Invertible geophone



April 17, 1951 K. w. M LOAD 2,

' INVERTIBLE GEOPHONE Filed Oct. 5, 1948 3 Sheets-$heqt 1 INVENTOR arw g ATTORNEY KENNETH m MELOAD.

April 17, 1951 w, MCLQAD I 2,548,990

INVERTIBLE GEOPHONE 7 Filed Oct. 5, 1948 I 3 Sh'eets-Sheei 3 will!" INVENTOR KENNETH MFLOAD BYM dW I TORNEY age generated by the geophone for upwardmove' Patented Apr. 17, 195i NITE poration of New York AppIicatio'EOCtoheiF; 1948, serial Nof 52943:

19 Claims." (Cl.

This' invention pertains' to the art of seismicffexploration and relates more specifically to-irhprovements in vibration sensitive devices in which" electrical impulses corresponding with artificial-1y created seismic waves are generated.

In seismic prospecting it is custom'aryto create seismid-waves in the surface of the earth by' detonating a charge of explosives. Waves-thus generate'd 'emer'ge from' the point of'detonation and travel by'va'rious paths to'detecting stations 10- or geophone location's. The geophones generate electrical signals insympathy with the seismic waves which, after amplification, are recorded generally by means of a record-ing galvanometer. The recording apparatus has associated there-" with means for indicating "the instantof' deto- 1 nation and a T timing device for placing time" "i markers on the record at regularly spac'e'd'intervals. 'With a knowledge of the total elapsed time between the instantof detonation and-the arrival 20 of waves'at'a detecting statio'nf-the'depths of reflecting interfaces orrefracting strata-maybe computed.

The geophones are usually-' located at regularly spaced points along a line "and are necessarily -25 oriented in such'aposition that'the instantaneous T voltage of a geophone will be of" proper polarity with respect to the seismiowaves to bdrecordd and of the same polarityas other geophones;in-a spread. Conventional geophones must be placed in the proper position and connected in proper' sense with respectto polarity in order'that a'distinction may be made between upw'ard'an'd downward motions of the earth.- Conventional'detectors reverse their phase by 180 degreesi'f'in' vertedirom a normal position. i

In carrying out the present invention there is' provided a vibration sensitive deviceiwhich 'may' I be operated in either of two positions: The volt-"V mentin-either of its two operative positions will be of the same sense. Broadly, a preferredform' of the-invention is characterized'by the provision of two vibratingsystems with a coupling'between the two systems for generation of a voltage-upon variation in the relative positions thereof. The device issoconstructed that one or the other of the vibrating systems is= immobilized when in either-oftwo operating positions. In one form the geophone comprises a-pairof inertia elements go resiliently mounted from an intermediate" sup- 1 port. The intermediate 1 support, in turn; :is'

mounted movably withrespect to a baseor hous ing. By movably mounting the-intermediatesup port, the vibrating systems comprising the inertia 55 be immobilized; Atr ansducer coupled to'inertia- L elements generatesa'voltage dependent'upon the 4 generated, and 'for'nqoveme nt awayj from'one an other, voltage of'the oppositsignis generated 'if'of the g 'e'ophoneof Fig. 1

- electric crystal asthe' generating-meme the invention has beenillustrated having' tWo I vibrating :systems' comprising" two permanent a' s magnets l0 and .i I, supported byleaf'spring'sd'l "ture 14.: The ileaf'spring lz is rigidly fastened' to the magnet structure"!!! under the clamping :plate 15 secured by screws I 6;

' other end of-the 1eafispring"=l'2is secured 'upperend of the intermed iat"'supportI f u der m elements resiliently mounted fromthe inter mediate support will, due to gravity, assume-dif ferent fixed positions withrespectt'oithe housing in ea'chof the two operative positions. *Whe nin: either operative position one inertia-elementwill relative p'osit'ionso'r the change 'ih therelative positions'of the inertia elements/- For movement toward one another, voltage offone polarityis The phase of the voltage generated depends not upon the position" the geophone occupies, but 1 upon the direction of movement, of orie oi the inertia elements with respect-to the other.

For a more'det ailed exp1anation'-'or the inven' tion, 'reference-maynow befhad'tothe following 1" description taken 'with'the accompanying"draw-- ingsyin whichz" V Fig. I'is a perspective 'view,'pa'rtly"in section of one form'of detector embodying the present invention; V g A I H I Fi 1d diagrammatically illustrates one,mode' of operation of the geophone Qf'Fig, 1; Fig, lb illustra'te's a"s e'cond mode of'op e FigJZ-is a perspective viewfpartly "ctio li 0f a modified form of' the invention withpertain partsomittedf Fig. "3 is a perspective view, partly in section,"

of a furthermodification of"a geophone embody ing the present-invention;-

7v V Fig. '4 is a cross-sectional'view' of"the inertia" elements of FigPS 'taken on the plane -4 4 thereof} v N Fig. 5 isa perspective-view,partly ection, which illustrates the invention u'tilizing' :Fig. 6 is a modificatiori of a 'portion of' Fig'. utilizingan elongated?piezoelectric blocl ias the generating elementj'and I r Fig. 7 is a perspective view, partly in seotion, of a length of cable which includes a'geophon Referring now: to .Fi'g.v 1;:a "geophone utilizing and I3 from an intermediate supporting struc Similarly} the th gap change the reluctance of the path. As a result the total flux traversing the magnetic flux path is varied. A suitable coil, diagrammatically illustrated by the series windings 20 carried by the magnets I and II, links or encloses the flux path. Voltages generated in the windings 20 are proportional to the rate of change of the flux linking them. The coil as illustrated is so wound that voltages generated in the series windings on the four pole pieces are additive in polarity.

The intermediate support I4 is movably mount-.

ed as by leaf spring from a primary support I which may be astructure to be enclosed in a geophone housing. The supporting structure is generically represented by the elements ZI and 22 secured to the end 23 of the housing. One end of the leaf spring 25 is clamped in or secured to the intermediate support I4; the other end is rigidly secured to the frame as between mounting members 2I and 22. The leaf spring 25 in its unflexed position lies in a plane parallel to and intermediate the planes of leaf springs l2 and I3. The leaf spring 25 is of such resiliency that the intermediate support It, carrying the magnetic structure including the magnets I8 and II, for either of two positions allows one of the two magnets (III or II) to rest upon a support or fulcrum provided adjacent each magnet. More particularly, a fulcrum indicated by a knife-edge or wedge 38 fastened to the side 31 of the geophone housing will, for the position illustrated in Fig. 1, carry the weight of the magnet I I. In this position, that is, with the side 3! of the geophone resting upon the ground, seismic waves received will cause the magnet I I to move toward oraway from the magnet III. The magnet It will remain substantially stationary with respect to a fixed point in space due to the inertia of the suspended mass. In this position an impulse from below causes a decrease in the length of the air gap and, consequently, lowers the'reluctance of the flux path. Assuming that the voltage thus generated causes the terminal 33 tobe positive with respect to terminal 32, movement of the magnet I I away from magnet II! will cause terminal 33 to be negative with respect to terminal 32.

If the geophone is placed with the side 35 on the earth, the intermediate support I4 carrying the magnets II] and II will change position so that the magnet II] will rest upon a fulcrum 35 fastened to the side 35 of the geophone housing. In this position an impulse from below causes the magnet II] to approach the magnet I I, thus decreasing the length of the air gap. As.

in the other operative position, the terminal 33 will be positive with respect to theterminal 32 as magnet I0 approaches magnet II. In either position the instantaneous polarity of the voltage generated with respect to an impinging seismic wave will have the same phase. Thus, there is provided a geophone which may be operated in either of two positions in which the voltage generated will be of the same instantaneous phase with respect to ground motion.

. a modified support for the member I4 has been geophone housing.

Detector units comprising the magnets I0 and I I are generally known as variable reluctance detectors. It is apparent that other types of detectors may be utilized. However, regardless of the particular shape or design of detector unit used, it is necessary that the natural periods of the two suspensions or vibrating systems are the same. As is well recognized in the seismograph art, geophones having natural periods low with respect to the frequencies of the seismic waves to be detected are generally preferred. Accordingly, the length, width and stiffness of the springs I2 and I3 will for each design be chosen in accordance with well known principles of mechanics to effect suspensions having the desired frequency characteristics.

The leaf spring 25 of Fig. 1 is preferably of substantial width to prevent lateral movement or wobble of the suspended magnets Ill and I I. To stabilize the suspension, a slideway or channel may be provided in which the intermediate sup port I4 may travel. As shown in Fig. 1, guides 24a and 24b fastened to side 3! of the geophone housing, and guides 24c (partially broken away) and 24d fastened to the side 35, are so positioned that the support i4 may move freely along a line lengthwise thereof and is prevented from moving or vibrating laterally.

The geophone illustrated in Fig. l willoperate in one of two modes depending on the location and type of the support upon which the lower magnet rests. In Fig. 1 and in the diagrammatic view of Fig. 1a Where corresponding parts have been given the same reference characters, a knifeedged fulcrum 35 located at the center of percussion of the suspension, which in this case includes springs I3 and 25, serves to support the vibrating elements. An impulse from below will cause the magnet I0 and the intermediate member I4 supported by both springs I3 and 25 to move relative to the case. The maximum amplitude position of the geophone elements when subjected to an impulse from below is illustrated by the dotted lines in Fig. 1a.

A different mode of operation obtains if a support for the lower magnet illustrated in Fig. 1b is utilized. In this case, the support 38a, which in practice may be the bottom of the case, extends throughout the length of magnet I I, spring I3 and the intermediate support I l. The magnet II and the intermediate support I4 both are fixed with respect to the case with the magnet II] being free to vibrate upon application of an impulse thereto. lustrated in Fig. 1a, the magnet III and the intermediate support I4 both vibrate, and the magnet II rotates slightly about the point of support. In Fig. 1b the intermediate support I4 and the magnet II are immobilized with only magnet Ifl free to vibrate.

A system vibrating in the second mode utilizing illustrated in Fig 2. For convenience, parts corresponding to those of Fig. 1 have been given the same reference characters. support I4 is mounted in a slideway which comprises members 25 and 26a secured to plate 21 which in turn is fastened to the end 23 of the Four rollers 28 (three of which are shown) complete the slideway for support I4. In the position illustrated, the intermediate support I4 and magnet I I rest upon the bottom SI of the geophone case. The magnet III is thus freely suspended, and magnet II is im- Thus, with the construction il- The intermediate earth decreases the length of the air gap between the magnets and Il. When the geophone is inverted, the intermediate support Mmay travel over rollers 28 to the second operative position. The support I4 and the magnet lfl'will then rest .upon the side 35. Upward movement of the earth, as in the other position, decreases the air gap length. The springs l2 and I3 extend the full width of their respective magnets and are secured under plates and lfia. In this modification, the support It and the lower magnet rest upon the geophone housing. The rollers 28 allow' the support [4 to travel freely from one operative position to' the other. With the intermediate support !4 thus gravitationally positioned, the phase of the voltage generated with respect to ground motion is the same for either operating position. 7

Referring now to Figs. 3 and 4, a two-position, single-sense dynamic geophone is illustrated as comprising an inertia member ti! supported from the intermediate member It by leaf spring l2, and a second inertia member 4H supported from the other end of the intermediate member I4 by the leaf spring l3. In the detailed sectional View of Fig. 4 the inertia element 48 is illustrated as comprising a mass 42 of non-magnetic material to which there is attached a tubular form or spool 43 which carries a coil as. The conductors 45a and 46a connect the coil 44 to terminals 45 and 46 which in turn are connected to the geophone terminals 32 and 33 as shown in Fig. 3. A screw 41 rigidly secures the coil form 43 to the mass 42. The inertia member 4| includes a cylindrical permanent magnet 50. The magnet 50 is fastened to a disc 5! of soft iron or other magnetic material as by a screw 52. A soft iron cylinder 53. closed at one end by and secured to disc BI, is of length equal to the length of the permanent magnet 50. A soft iron ring 5 1 is fastened to and concentrically with the cylinder 53 and forms a pole piece adjacent the magnet 50. A radial magnetic field exists in the air space between the upper end of magnet 50 and the pole piece 54. With the inertia structure 46 suspended in coaxial relationship with the inertia structure 4!, movements therebetween will generate a voltage therein upon variations in the magnetic flux linking the coil 44. The instantaneous polarity of the voltage generated depends upon whether the structure 4| is moving toward or away from the structure 48 01', stated another way, whether the flux linking coil a4 is increasing or decreasing. By mounting the inertia structures 36 and 41 from the intermediate support M as by the springs I2 and I3, relative movement between the inertia members causes a voltage to be generated. As shown in Fig. 3, with the inertia member 4i immobilized, the inertia member 40 is the only one free to move with respect to the case or geophone housing. Consequently, upward movement of the earth will cause the element 4! to move toward the element 60. Similarly, when the geophone is inverted the inertia element M] is immobilized, and the inertia element 4| is free to move with respect to the geophone case. As characteristic of the devices of Figs. 1 and 2, the

' polarity or phase of the voltage generated is independent of the geophone position.

In the structure of Fig. 3, as in all modifications of the present invention, the natural frequency of vibration of the two suspended masses should be the same. It is evident that dissymmetry of suspension or different natural frequencies of the suspended inertia elementswould cause the geophone outputin one operating 1305i? tion to diifer from the output in the-other oper-* ating position. However, by selecting materials so to produceelements 40 and 4| of Fig. 3 having the same mass, the geophone output will be the same for both operating positions not withstanding any dissymmetry in the configuration of elements 4!] and 4|.

It is to be noted that since mass is nonmagnetic, there is no force of attraction between the two suspensions and, thus, no tendency to lock or freeze the detector as is characteristic of variable reluctance type detectors such as shown in Figs. 1 and 2. A further advantage of this form is that parts cylindrical in shape lend themselves generally to more economical construction.

The geophones illustrated in Figs. 1-4 utilize an electromagnetic coupling between the two vibrating systems to convert elastic waves or ground movements into electrical impulses.v It will be recognized that the magnitude of the voltage generated is proportional to the velocity with which one element approaches or recedes from the other element. Geophones having an output proportional to displacement are illustrated in Figs. 5 and 6 where a mechanical coupling between the inertia elements is utilized. In the device of Fig. 5 mass 18 is suspended by a bifurcated leaf spring H from one end. of an intermediate support 12. Similarly, a mass '13 is suspended from the other end of the intermediate support 12 by a bifurcated leaf spring 14. Leaf spring 15 resiliently supports the intermediate member 12 from the geophone housing orcase. An intermediate portion of each of the-bifurcated springs H and I forms the projecting tongues Ti and 13, between the extremities of which is mounted a block 39 of piezoelectric material. The piezoelectric material or crystal is so oriented with respect to the retaining tongues 17 and I8 that pressure exerted thereupon due to vibration of, or relative movement between the masses Hi and 73 gives rise to a voltage between a pairof faces other than those upon which the tongues ll and i8 exert pressure. As illustrated, conductor 8! makes contact with the end 83 of the crystal 80'; conductor 82 is electrically connected to the opposite end of the crystal 80. The masses l0 and '53, the intermediate supporting structure 12 and spring mountings TI and M are in a manner character istic of the present invention movably mounted as by spring 15 so that for either of the two operating positions of the geophone only one of the two masses is free to vibrate, and the other is immobilized, resting upon its associated fulcrum or upon the case itself.

A decrease in the distancebetween masses ii and 13 causes the pressure exerted by tongues and 18 to increase, thus increasing the crystal output. The pressure exerted, thus the voltage generated, is proportional. to the amplitude of ground movement. In Fig. 6, where elements corresponding to those in Fig. 5 have :been given the same reference characters, the quartz orother piezoelectric element 80, instead of being a block as in Fig. 5, is an elongated element or slab which the masses 1!] and'73 causes the crystal or pi'ezoelectric slab 80 to be twisted. Stated otherwise, pressure exerted by-the tongues lland '18- upon relative motion between the inertia masses distorts the crystal slab 80 from its normal planar configuration. Conductor 8| connected to contact 81, and conductor 82 connected to a contact similar to contact 81 and positioned on the crystal face opposite thereto, detect the voltage generated due to the mechanical deformation of the crystal slab 80. It is obvious that no matter which of the two springs H and M of the geophone is uppermost, upward motion of the earth causes an increase in the torque as indicated by arrow 88.

Geophones embodying the invention may be utilized in regular seismograph exploration in the place of prior art geophones, eliminating the necessity of positioning each geophone in a spread in like operating positions. Geophones constructed in accordance with the foregoing description are particularly suitable for the construction of, and use in, a prefabricated exploration cable. A section of such a cable is illustrated in Fig. '7. A modification of the construction of Fig. has been illustrated though any of the other forms may be used.

The geophone comprising two vibratory systems mounted in its housing is molded in a fabric reinforced rubber sheath 99. The geophone housing and the sheath 9% have been partially broken away to illustrate the orientation of the geophone. The lower vibrating system comprising the spring 14 and the inertia element 53 attached to the lower end of the intermediate support 12 rests upon the bottom or the lower side of the geophone case. The upper vibrating system including spring H and the inertia element is freely suspended. The action of the spring mounting the intermediate support causes one of the two vibrating systems to be immobilized.

The geophone is enclosed in the cable in a section where the rubber sheath 90 has one crosssectional dimension enlarged. The other crosssectional dimension remains substantially constant throughout the length of the cable. The rubber sheath also encloses a plurality of pairs of electrical conductors 9i. Geophone conductors 8i and 82 are connected to a selected pair of the conductors 91. A complete exploration unit or cable includes a plurality of such geophones so enclosed at predetermined points along the length thereof. Each pair of the conductors 9| is connected to one geophone included in the cable, or, if desired, one Or more geophones may be connected to each pair of conductors. The geophone housing is rectangular in cross-section with its elongated sides parallel to the planes of the springs ll, 14 and 15. By providing a narrow, fiat housing, each geophone automatically will position itself on a flat side.

As illustrated in Fig. 7 the conductors 9| enclosed in a portion 92 of the sheath 9% are preferably divided and are positioned on both sides of the cable geophone. Half of the conductors, 9la, are bundled together and pass along one side of the geophone, and the other half, conductors 91b, pass along the othe side of the geophone.

The cable is a unitary structure with slightly enlarged portions at each geophone location or position. It may be wound upon a reel and otherwise manipulated as any other rubber insulated cable. The cable is merel unreeled from a truck or other vehicle while traveling the length of a spread to position it to receive seismic waves. The cable in portions intermediate the geophones may be either square, rectangular, or round.

However, at the geophone location it is rectan'gular, having the sides parallel to the suspension springs 1 l 14 and 15 elongated and the other two sides relatively narrow. Geophones encased in such portions of the cable automatically will be oriented in one of two operating positions as the cable is unreeled. No further adjustments or preparations need be made before taking a seismic record.

The particular embodiments of the invention described may be taken as illustrative. The dimensions and the relative proportions of the inertia elements, the springs, and the intermediate supports may be varied or modified to satisfy particular requirements as long as two vibrating systems having the same natural period are supported in such a manner that one of those vibrating systems will be immobolized when in either of two operating positions. The generating element, responsive to the spacing or change in spacing between the inertia elements, produces a voltage proportional to displacement or velocity of the earth. It is to be understood that displacement detectors of the strain-gauge type may be utilized in place of the piezoelectric elements of Figs. 5 and 6 which will cause a change in circuit resistance proportional to displacement.

Though several modifications of the invention have been illustrated and described, it is to be understood that further modifications may now suggest themselves to those skilled in the art all within the scope of the appended claims.

What is claimed is:

l. A vibration sensitive device which comprises two vibrating systems, means coupling said vibrating systems for generation of a voltage upon variations in the relative positions of said vibrating systems with respect to each other, and means for selectively immobilizing one of said vibrating systems when said device is in one of two operating positions and for immobilizing the other of said vibrating systems when said device is in the other of its operating positions.

2. A vibration sensitive device which comprises two vibrating systems, means coupling said vibrating systems for generation of a voltage upon variations in the relative positions of said vibrating systems with respect to each other, and means including a resilient mounting for said vibrating systems for selectively immobilizing one of said vibrating systems when said device is in one of two operating positions and for immobilizing the other of said Vibrating systems when said device is in the other of its operating positions.

3. A vibration sensitive device which comprises two inertia elements resiliently supported from an intermediate structure, a coupling between said inertia elements for generation of a voltage upon variations in the relative positions thereof, and means resiliently mounting said intermediate structure for movement into one position for immobilizing one of said inertia elements when said device is in one of two operating positions and fo movement to a second position for immobilizing the other of said inertia elements when said device is in the other of its operating positions.

4. A vibration sensitive device which comprises two vibrating systems, means coupling said vibrating systems for generation of a voltage upon variations in the relative positions of said vibrating systems, and means including a slidable mounting for said vibrating systems for movement of one of said systems to a position where it will not vibrate upon movement of said device to one operating position and upon movement oi said device to a second operating 'posiiontwillmove theother of rsaid-vibratingsystems 2 to a position-where it will not vibrate.

5. Auvibration; sensitive device which comprises two inertia elements, resilient supportsforgsaid .elementsiextending from an intermediate, structure, a coupling between. said inertia elements for generation of a voltage. upon variations in the v:relativepositions thereof, means slidably-mountsing saidiintermediate structure, and means engaging .one ofsaidinertia elements when said device is in; one of two. operatingpositions and 'r'for' engaging the :other of said elements when said device is in.a second operating position'se ...-.-.lectively to render; effective one or theother of '1 ;the .resilientsupports forsaid elements.

.6. A" vibration sensitive device: disposed within 'ie-ahousing which comprises a frame, two inertia ele- .ments, :resilient gsupports extending from said 'a;;.frame for said elements to,form tWo Vibrating ii :systems, .means. .co'uplingjsaid vibratingsystems rafor. generation of a voltage uponvariation in the relative positions thereof, and slidable mounting 2;: means for. said framefor limited movement toward one wall ofgsaid.housing,' means rigidqwith i .rsaid 'wallforimmobilizing.one of said inertia elenients..: when said frame. moves in the direction thereof; and means rigidwith the .oppositewall of upomm'ovement of said .frame in its direction. J7. .Avibration sensitivedevice for generating a 1':lvoltageiwhosenpolaritmz: for .a givendirection of :znground motion, isthe same in either of two oper- -.'i atingrposition's of said devicewhich comprises a r ..support;.two inertia elements resiliently mounted upon said support forming two vibrating systems i magnetically.coupledrtogether, :means associated 1 :withasaid magnetically ;.coupled systems; for ,gen- I erating a voltage proportional to the .rate of iohange of.. saidmagnetidcoupling between v said inertianelements; and'means. for selectively immobilizing one of said inertia elements when said "device is in one 10f; twooperating positions; and for when said deviceis in the other of itsoperating 2:"; positions.

8."A vibrationsensitive' device for generating a ing 'aamagnetic fluxi'path,".electrical'conductors linking-said flux path for generation of a voltage proportionalto the rate of'changeof thespacing '1: :between said 'magnetic structures,:-:.and emeans -m'ounting said supporti'gravitationally to position with respect to said support whilerallowing the other magnetic. structure freely to vibrate thereby to generate a voltage whose polarity is independent of which magnetic structure is in saidwfixedrelation.

9. A vibration sensitive device forrgenerating-a voltage whoselpolarity, fora given direction of ground motion; is the same in either of two operatmg positions which comprises a housing, an interme'diate support, 1 two permanent,-magnets, means incl'uding-springs mountingone of said other magnet from the opposite end ofr said support with their pole faces in oppositely poled spaced relationship and forming two vibrating systems having the same resonant frequency, a

th'e housingv engaging: the :other inertia element imm'obilizinga-the: other of. said inertia elements "=vo1tage1whose polarity,:' for a given direction of --magnetsfrom one end of -='said support and the I i coi1 .lin k ingthe flux. path formed bysaid opposite- 1 1y poled magnetsfor-generation of. a voltage-proportionalto the rate of, change of the spacing a between said ;magnets,,- and means movably 5, mounting said support-within said housing. gravitationally to position said support andone of i said vibratingsystems in'fixedrelation to said housing with said device in the-first of it two operating positions and'gravitationally to, position saidsupport and the other of said vibrating -...systems in fixedi relation to said housing with 1 the device init other; operating position.

10. A vibration sensitive device'for generating a voltage the. polarity of which for a given direction of ground motion isthe same ineither of two .:,0pe1ating positions which comprises a support, two inertia elements resiliently mounted upon i said support formingtwo vibrating systems, means electromagneticallyooupling said vibrating systems forgenerationof a voltage proportional to the rateofchange ofthe relative positions. thereof; and-means for immobilizingone of said inertia elements; when said device is in the first of said "r'operatingpositions and for immobilizing the vother of said inertia elements when said device is in'the secondofits said operating positions. 11. A vibration sensitive device for generating a r; voltage the polarity of which for-agivendirection of ground. motion is the same in either of two operating positions which comprises a support, two inertia elementsresiliently mounted upon "said;- support forming two vibrating systems, one of saidinertia elements includingamagnetic circuit having an air gap, the other-inertia element 35, including a.1coi1,: said inertia elements mounted =.-.with said'coil insaid, air gap forgenerating a voltage proportional to: the velocity and direction of. movement otsaid ,coil in said airs apllpon .vibration' of saidinertia; elements, and means 40 mounting saidsuppor-t gravitationally topQSition one of said 'inertiaelements in.fixed relation to idsupport whenrsaiddevi e is in the first of i said operating. positions and for positioning. the other of, saidinertiagelements in fixed relation to .said support when; said device is in, the secon'dof saidoperatingipositions.

12. -A vibration sensitivedevice forgenerating a voltage the polarity of, which for a given direc- ,tion .ofyground motion is thesame in either of twooperating positions which comprises a housing, a. support, two inertia elements, springs mounting one of said inertia elements from-each end of saidsupport; said inertia elements being in. coaxial relationship, one of said inertia. ele- 5.5 ments including a cylindrical permanent .mag- :net, ,apole piececoncentrically positioned ad- .jacentoneend of said magnet, and spaced radiallyv therefrom and-forming an air. gap,,;means v itionionezofrsaid.magneticstructuresin'fixed relacompletinga magnetic; path between the other 6. endofysaid; magnet and said-polepiece, said seoondinertia element-includinga.massiand a "coil, saidcoil positioned inssaid air. gap and en- :& circling said magnet for-n gener'ation of. a.-'ivoltage Z therein upon; variation in the relative..,positions Q of. said inertiaelements;and-means. movably .:-,mou nting said support-within said housing gravitationally to. position said support (and. one of said inertia ;elements in: fixed :relationwith said .e-rhqusing :when said device is in thefirstofsaid '10 =ope.rating positions. and fol-positioning: the .other 7 ref said; inertiaelernents-gin fixed relation with said 5:. g housing when said; deviceiisdn the-second of said operating positions.

13. A vibration sensitive device for generating a Voltage whose polarity for a given direction of ground motion is the same in either of two operating positions which comprises a support, two inertia elements resiliently mounted on said support forming two vibrating systems, means mechanically coupling said vibrating systems for generation of a voltage proportional to the amplitude of relative movement therebetween, and means mounting said support for immobilizing one of said vibrating systems when said device is in the first of said operating positions and for immobilizing the other of said vibrating systems when said device is in the second of said operating positions.

14. A vibration sensitive device for generating a voltage whose polarity for a given direction of ground motion is the same in either of two oper ating positions which comprises a support, two inertia elements, springs mounting one of said inertia elements from each end of said support and in spaced relation one to the other forming two vibrating systems, means including a piezoelectric generator coupling said vibratin systems for producing a voltage upon variation in the spaced relationship between said elements, and means mounting said support gravitationally to position one of said elements in fixed relation with respect to said support while allowing the other element freely to vibrate thereby to generate a voltage Whose polarity i independent of which of said elements is in said fixed relation.

15. A vibration sensitive device for generating a voltage whose polarity for a given direction of ground motion is the same in either of two operating positions which comprises a housing, a support within said housing, two inertia elements, bifurcated springs mounting one of said inertia elements from each end of said support, said hifurcated springs having intermediate portions thereof forming curved tongued extensions, a piezoelectric crystal mounted between the extremities of said tongues, circuit-forming means contacting said crystal for detecting voltages generated upon changes in the pressure exerted due to changes in the relative positions of said vibi'ating systems, and a mounting for said support for positioning one of said inertia elements and said support in fixed relation with said housing when said device is in the first of two operating positions and for positionin said support and the other of said inertia elements in fixed relation with said housing when said-device i in the second of said operating positions.

16. A vibration sensitive device for generating a voltage whose polarity for a given direction of ground motion is the same in either of two operating positions which comprises a housing, a support within said housing, two inertia elements, bifurcated springs mounting one of said inertia elements from each end of said support, said bifurcated springs having intermediate portions thereof forming 'curved tongued extensions, an elongated piezoelectric crystal slab fastened to and electrically insulated from said support extending between and obliquely of the extremities of said tongues, circuit-forming means for detecting voltages generated by said crystal upon deformation of said crystal from its normal planar configuration due to pressure exerted by said tongues upon vibration of said inertia elements, and a mounting for said support for posilomng one of said inertia elements and said support in fixed relation with said housing wh n I 12 said device is in one of two operating positionsand for positioning the other of said inertia elements and said support in fixed relation with said hous' ing when said device is in the other of said two operating positions.

17. The combination with a flexible cable, of' a series of geophones housed at spaced intervals within said cable and whose relative orientations may differ for different spread locations, said" cable having such cross-sectional shape that eachgeophone will assume one or the other of two po-- sitions and each of said geophones comprising two vibrating systems, means to immobilize one of said systems when in the other of said positions and for immobilizing the other of said system when in the other of said positions, and a common coupling between said systems to produce avoltage whose phase is independent of which vibrating system is immobilized, the aforementioned shape of the cable and the construction of the geophones insuring constant phase relation of the outputs of the series of geophones independent of their orientation.

18. A seismic cable which comprises a plurality of vibration sensitive devices spaced one from another at predetermined intervals, electrical conductors connecting each of said devices, a sheath enclosing said devices and conductors forming a unitary system, each of said devices having two vibrating systems, means for generating a voltage proportional to changes in the spaced relation between said systems, and means for'immobilizing one of said systems when in the first of two operating positions and for immobilizing the other of said systems when in the second of said two operating positions, said cable having one cross-sectional dimension elongated at each geophone location forming fiat face perpendicular to the direction of movement of said vibrating systems automatically to orient each geophone in one of said two positions when placed on the earth.

19. The combination of a flexible cable characterized by having one transverse dimension elongated at least at spaced sections along the length thereof, a vibration sensitive device housed in each of said sections and comprising two vibratory elements with means for coupling said vibratory elements for voltage generation upon variation in the relative position of said elements, and means for mounting said vibration sensitive device in said cable gravitationally to position one of said elements of each of said devices in fixed relation with respect to said cable while allowing the other element of each of said devices freely to vibrate for generation of voltages having the same polarity for the same direction of movement of the vibratory elements independent of which of said elements of said device is in said fixed relation.

KENNETH W. MCLOAD.

REFERENCES CITED The following references are of record in the file of this patent: T 1

UNITED STATES PATENTS I 

